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A GIS/LIS Approach for Study on Suitability of Shallow Foundation at Southern Chennai, India

S. Rajesh
Lecturer
Department of Civil Engineering
Vellore Institute of Technology
VIT- Deemed University, INDIA
hsrajesh79@yahoo.com

D.Sankaragururaman
Scientist - E
Division of Soil Mechanics
& Foundation Engineering
Anna University, INDIA

Ashutosh Das
Lecturer
School of Civil Engineering
SASTRA Deemed-University
Thanjavur, INDIA
dasa16108@yahoo.com


Abstract
The tedious bore-log studies or costly specific subsoil investigation techniques, demand the necessity of a GIS / LIS based database system. In the present paper a synoptic analysis of the safe bearing capacities of the soil in southern part of south Chennai of India and subsequent digitization at various depths ( using of ‘surfer’-based-kricking-interpolation technique of borehole data). Using Arcview/ArcInfo, the iso-standard penetration number (SPTN)-StrengthTest (representing bearing capacities of the soil) was integrated with the base map as well as the generated/interpolated thematic maps to obtain user-friendly Foundation-Suitability Maps, whose validity were verified in the site upto a high precision accuracy. The present research work is expected to play an important role for geotechnical feasibility study of any location in the site studied.

Introduction
With the development of economic activities in the world, the construction activities have also increased manifold. In order to assess the general suitability of the site and to prepare an adequate and economic safe design for the proposed work, proper sub surface investigation is to be made. The primary objective of subsoil investigation in civil engineering is to determine stratiagraphy and pertinent properties of soil underlying the site. The sub-soil stratum below the ground is always complex. Traditional method of soil investigation includes boring (or) drilling, test pits, plate/ footing load test, sounding/ probing, dynamic soil test, analysis chemical and engineering parameters of soil or rock sample in laboratory and so forth. Later with the introduction of various indirect methods (involving geophysical investigation such as electrical conductivity test, seismic refraction and magnetic methods) and expansive application of remote sensing techniques in the soil mapping, now more synoptic coverage could be obtained. With the introduction of Geographic Information System (GIS) at present, not only the missing spatial data could be generated to cope with existing geographically referenced data and the corresponding attribute information, but modeling and simulation for specific requirement and fore costing can also be carried out.

The use of GIS in geotechnical investigation has been rather recent in comparison to its own applications such as water resources, agriculture, geology, metrology etc., . As for as geotechnical engineering is concerned inclusion of the spatial attributes of the data is itself a significant advance over common practice, where the spatial component of these data is often ignored through the averaging of multiple data values from different location and application of a safety factor to account for variability among other factors. The soil as a whole is a complex material, it is always heterogeneous and non-isotropic because of which profile of soil will be entirely different from place to place.

In order to decide the suitability of foundation for any structures, any location, and any loading, the bearing capacity of soil is to be determined. Safe bearing capacity of soil (SBC) refers to the maximum net intensity of loading, which can be allowed on the soil without the settlement exceeding permissible value (1). SBC of the soil can be determined by sub soil investigation. However, due to expensive subsoil investigation works, the present research was undertaken taking the advantage of the spatial continuity and variability of this important geotechnical parameters to develop a user friendly suitability map for shallow foundation.

In order to develop a comprehensive spatial database the present work was carried out using Arc- info/ Arcview at 1: 12500 scale. The study was carried out for a small region in the south of chennai, India. The work involves development of spatial framework using available maps and GPS survey, followed by digitization, building topology, verification and analysis. The primary data used for the work includes area of state boundary, bore log data, soil survey data, village boundary data where as the derived data includes soil map, Iso penetration resistance map and suitability map.

Study Area
The study area involves Kalikundram, Kottivakkam, Tharamani and Thiruvanmiyur of Chengalpattu district at the south chennai, India. The study area lies between 80° 15' 00" E - 80° 16' 50" E Longitude and 12° 58' 30" N - ---Latitude. The extent of the study area is 1058.2 Hectares with more than 5000 inhabitance. The area is semi-urban with majority of the population depending on various commercial and industrial setting in the near by city, chennai.

Generation of Primary Thematic Maps
The village boundary map obtained from the office of Chennai Metropolitan Development Agency (CMDA) consisting the study area were separately demarcated, digitized and blended to prepare base map. Land use map, which includes various landuse patterns, was obtained from CMDA and other sources as a raw map followed by digitization. The Transportation network consisting of roads, railways, MRTS and canals are collected from Highway research station (HRS) digitized in a separate layer. Borehole location map (Fig 1) with various geotechnical parameters (discussed in forth coming paragraph) was procured from various private consultant in non-spatial format and was geo referenced-using hand held GPS and subsequently digitized. A soil map (Fig 2) is prepared (with respective five predominant soil types namely clay overlain by silty sand, clayey soil, clay with embedded sand, sandy soil, silty sand with overlying clay sediment) by actual sampling aided by GPS.




Iso – Penetration Resistance Map
From the subsurface investigation SPT N(standard penetration resistance – number for blows for 30 cm penetration, gives indirectly SBC of the soil) at different depths were inputted in the Surfer (Copyright Golden Software Incorporated, 1993-96: for windows version 6xx). By using Kriging interpolation technique, Isolines or Iso SPT N contours were generated at their respective depths. These ISO SPT N contours were converted into Arc coverage. The Arc coverage was edited, cleaned, projected and transformed to form Iso SPT N map. Attributes are added to this thematic map.

Derived Soil SPT N Map
The integration of Soil and Iso SPT N map gives a very practical and significant outcome of this research work. The strength and soil properties can be easily estimated at any location within the study area with simple queries . Generally shallow foundation will be laid within 1.5 m from the ground level. In order to decide the suitability of shallow foundation Iso SPT N @ 1.5 m from the ground level is overlaid with Soil map.

Suitability Map
The suitability of the shallow foundation is decided by two important governing factors namely allowable bearing capacity also referred as allowable load intensity (ALI ) and super imposed load (load from each floors). Allowable bearing capacity can be computed using Teng’s relation (1). The program for the suitability of the shallow foundation is written in Avenue language. The parameter used for the suitability analysis are SPT N value, width and depth of the foundation, level (terrain) of the ground, ground water table, and soil type. This program will automatically take the values of SPT N from Iso SPT N map with respective depth and the soil type will be fetched from Soil map. For an following input, width of the footing as 2m , depth of the foundation as 1.5 m from ground level (G.L), water table is far off from G.L, G.L is fairly level, Suitability map (Fig 3) is generated. For this input, five zones are demarcated. Zone 5 – highest ALI ( i.e., > 600 KN/sq.m) regime has been observed towards north and middle eastern regions with sporadic northern pockets. This zone is well suited for shallow foundation. The zone 2 to 4 (i.e., 100 – 600 KN/sq.m) are moderately suited for shallow foundation. Proper care has to be taken in zone 2 before designing the foundation. The zone 1 (i.e., <100 KN/sq.m) , unsuitable for any shallow foundation, especially footings.


Conclusion
The present research work aiming the suitability of shallow foundation using GIS/ LIS for the southern part of Chennai, India will be very useful for all Civil engineers, Geotechnical Engineers, Design Engineers, Planners and even the local inhabitant for any future developmental activities in the area concerned. In fact, for any specific location, with suitable queries, the allowable load intensity of soil and the suitable foundation can be obtained, which is found to be close to the actual findings at this location. Another advantage with the present work is its flexibility with respect to adding data as well as adding few non-spatial parameters like depth of water table, surface drainage pattern, soil permeability and infiltration capacity and so forth.

References
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